Method of operating a fluid jet cutting machine with abrasive removal system

ABSTRACT

A method of operating a fluid jet cutting machine with abrasive removal system. The fluid-jet cutting machine has a nozzle and a carrier assembly attached to the nozzole to move the nozzle along a cutting path. A high-pressure fluid source and an abrasive particle source are coupled to the nozzle to generate an abrasive fluid-jet having a fluid and a plurality of abrasive particles for cutting a work-piece. The cutting machine also has a particle removal device including a tank aligned with the nozzle, a settling container, and a fluid transport mechanism to transport fluid from the tank to the settling container. The tank includes at least one compartment configured to receive the fluid and the abrasive particles of the fluid-jet along at least a portion of the cutting path. Additionally, the compartment is configured to control fluid flow within the compartment so that the fluid-jet suspends, and maintains the suspension, of at least a substantial portion of the abrasive particles in the one compartment without additional mechanical agitation. The fluid transport mechanism can include a conduit with a first end in fluid communication with the compartment and a second end outside of the compartment in fluid communication with the settling container. In operation, a portion of the fluid with suspended abrasive particles in the compartment is transported through the conduit and into the settling container. The abrasive particles from the transported portion of fluid settle to a lower portion of the settling container while a clarified fluid is removed from the settling container.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a divisional of pending U.S. patent application Ser. No. 09/069,223, filed Apr. 28, 1998.

TECHNICAL FIELD

The present invention relates to fluid-jet cutting devices and methods, and more particularly to such devices including an abrasive removal system.

BACKGROUND OF THE INVENTION

Fluid-jet cutting devices are often used to cut metal parts, fiber-cement siding, stone and many other materials. A typical fluid-jet cutting machine has a high-pressure pump to provide a high-pressure fluid source, and a nozzle is coupled to the high-pressure fluid source to generate a cutting-jet from the nozzle. The nozzle is also attached to a carrier assembly that moves the nozzle along a desired cutting path, and a catch tank is aligned with the nozzle throughout the cutting path. An abrasive particle source may be coupled to the nozzle to impart abrasive particles to the cutting-jet. The fluid is typically water, and the abrasive particles are typically garnet.

In operation of such a fluid-jet cutting machine, a work-piece is positioned between the nozzle and the catch tank. The carrier assembly moves the nozzle along the cutting path, and the high-pressure fluid source and abrasive particle source generate an abrasive cutting-jet projecting from the nozzle. As the cutting-jet passes through the work-piece, the catch tank receives the wastewater and abrasive particles of the spent cutting-jet. The abrasive particles generally accumulate in the catch tank, and the waste water generally flows out of the catch tank.

One concern with fluid-jet cutting systems is that the abrasive particles must be removed from the catch tank. The devices and methods for removing abrasive particles from catch tanks typically depend upon the size of the catch tanks. In general, small catch tanks are typically less than 2′×4′, and large catch tanks are typically greater than 4′×8′.

Conventional techniques for removing abrasive particles from small catch tanks generally allow the wastewater to simply overflow the small catch tanks. Although a portion of the abrasive particles are removed from small catch tanks with the overflowing wastewater, abrasive particles still accumulate in small catch tanks. The remaining abrasive particles are typically removed from small catch tanks by: (1) stopping the cutting-jet to allow the abrasive particles to settle; and (2) shoveling or dumping the abrasive particles from the catch tank.

One problem with conventional techniques for removing abrasive particles from small catch tanks is that the cutting machine must be shut down for a period of time to allow the abrasive particles to settle. Removing abrasive particles from small catch tanks may accordingly result in a significant amount of down-time in a cutting operation. Another problem with removing abrasive particles from small catch tanks is that it is inconvenient and labor intensive to shovel or dump the abrasive particles from the tanks. Therefore, removing abrasive particles from small catch tanks reduces the efficiency and productivity of fluid-jet cutting processes.

Conventional techniques for removing abrasive particles from large catch tanks are different than those for small catch tanks. One conventional abrasive removal system for large catch tanks is a conveyor rake that moves across the bottom of a large catch tank and up a discharge side of the tank. To most effectively operate a conveyor rake, the abrasive particles must settle to the bottom of the tank. The conveyor then carries the abrasive particles from the bottom of the tank and over the discharge side of the tank. One potential problem with conveyor rakes, therefore, is that they may need to be operated when the cutting-jet is shut down causing down-time. Another problem with conveyor rakes is that they may be cut by the cutting-jet during the cutting process if the cutting-jet passes over the portion of the conveyor rake at the discharge side of the catch tank. Additionally, conveyor rake removal systems may be relatively expensive units with many moving components that may fail after extended use. Thus, conveyor rake systems for removing abrasive particles from large catch tanks have several drawbacks.

Another conventional system for removing abrasive particles from large catch tanks is a continuous centrifugal system that has a large pump in the catch tank and a centrifugal separator outside of the catch tank. The large pump agitates the wastewater to suspend the abrasive particles in the catch tank. The wastewater and the suspended abrasive particles are then pumped to a centrifuge, such as a hydrocyclone separator, to separate the abrasive particles from the wastewater. One drawback of this device is that large, expensive pumps are required to maintain the abrasive particles in suspension in the wastewater. Another drawback of this abrasive removal system is that a significant amount of energy is required to operate such large pumps. Additionally, hydrocyclone separators are also relatively costly devices that require additional resources to operate and maintain. Thus, centrifugal removal systems also have several drawbacks.

SUMMARY OF THE INVENTION

The invention is generally directed toward fluid jet-cutting machines and abrasive particle removal devices. In one embodiment, a fluid-jet cutting machine has a nozzle and a carrier assembly that moves the nozzle along a cutting path. A high-pressure fluid source and an abrasive particle source are coupled to the nozzle to generate an abrasive cutting-jet having a fluid and a plurality of abrasive particles. In general, the fluid can be water and the abrasive particles can be composed of garnet.

The cutting machine also has a particle removal device including a tank aligned with the nozzle, a settling container, and a fluid transport mechanism to transport fluid from the tank to the settling container. The tank includes at least one compartment configured to receive the fluid and the abrasive particles of the cutting-jet along at least a portion of the cutting path. Additionally, the compartment is configured to control fluid flow within the tank so that the cutting-jet continuously suspends at least a substantial portion of the abrasive particles in the one compartment without additional mechanical agitation. The compartment itself, for example, can be sized and/or shaped so that the jet energy alone maintains the abrasive particles in suspension. The fluid transport mechanism can include a conduit with a first end in fluid communication with the compartment and a second end outside of the compartment in fluid communication with the settling container.

In operation, a portion of the fluid with suspended abrasive particles in the compartment is transported through the conduit and into the settling container. For example, a fluid drive system may be coupled to the conduit to draw fluid from the compartment and through the conduit. The abrasive particles from the transported portion of fluid settle to a lower portion of the settling container while a clarified fluid is removed from the settling container. The clarified fluid may also be pumped back to the catch tank.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic isometric view of a fluid-jet cutting machine with a cut-away view of one embodiment of an abrasive particle removal system.

FIG. 2 is a partial cross-sectional view of the abrasive removal system of the fluid-jet cutting machine shown in FIG. 1.

FIG. 3 is a partial cross-sectional view of another embodiment of an abrasive particle removal system for a fluid-jet cutting machine.

FIG. 4 is a partial cross-sectional view of another embodiment of an abrasive particle removal system for a fluid-jet cutting machine.

FIG. 5 is a partial cross-sectional view of another embodiment of an abrasive particle removal system for a fluid-jet cutting machine.

FIG. 6 is a partial cross-sectional view of another embodiment of an abrasive particle removal system for a fluid-jet cutting machine.

FIG. 7 is a schematic isometric view of another fluid-jet cutting machine with a cut-away view of another embodiment of an abrasive particle removal system.

DETAILED DESCRIPTION OF THE INVENTION

The present invention is directed toward devices and methods for removing abrasive particles from fluid-jet cutting machines. Many specific details of certain embodiments of the invention are set forth in the following description and in FIGS. 1-7 to provide a thorough understanding of such embodiments. One skilled in the art, however, will understand that the present invention may have additional embodiments, or that the invention may be practiced without several of the details described in the following description.

FIG. 1 is a schematic isometric view of a fluid-jet cutting machine 10. In this embodiment, the cutting machine 10 includes a cutting head 20 with a carrier assembly 21 and a nozzle 22 attached to the carrier assembly 20. A high-pressure fluid source 24 and an abrasive particle source 26 are coupled to the nozzle 22 to generate an abrasive cutting-jet 28 projecting from the nozzle 22. Additionally, the cutting machine 10 also includes a work-piece support structure 30 with a number of support members or beams 32 attached to a frame 33. In operation, the carrier assembly 21 moves the nozzle 22 along desired X-Y coordinates (arrows M) to move the cutting-jet 28 along a desired cutting path P with respect to a work-piece W. One suitable cutting head 20 is the Bengal 4×4 and Paser 3 System manufactured by Flow International Corporation of Kent, Wash.

The cutting machine 10 also includes an abrasive particle removal system 40. In one embodiment, the abrasive particle removing system 40 has a catch tank 42 under the support structure 30, a fluid transport mechanism 44 in the catch tank 42, and a settling container 46 coupled to the fluid transport mechanism 44. As described in greater detail below, the abrasive particle removal system 40 continuously removes abrasive particles from the catch tank 42 without using mechanical agitators to suspend the abrasive particles in the waste fluid.

The catch tank 42 preferably has a bottom panel 50, first and second side-walls 51 a and 51 b projecting upward from opposing sides of the bottom panel 50, and first and second end-walls 5 c and 51 d projecting upward from opposing ends of the bottom panel 50. The first and second side-walls 51 a and 51 b are attached to the first and second end-walls 51 c and 51 d to form a large cavity. The catch tank 42 also includes a central divider 52 extending longitudinally within the tank 42, and a plurality of crossing dividers 54 extending transverse to the central divider 52. The dividers 52 and 54 define a plurality of compartments 56 (identified by reference numbers 56 a-56 f) in the tank 42.

The compartments 56 receive the waste-fluid 12 and the abrasive particles of the cutting-jet 28. Additionally, each compartment 56 is configured to control the fluid flow within the tank 42. For example, when the cutting-jet 28 is aligned with compartment 56 b, the dividers 52 and 54 defining this compartment control the fluid flow such that the cutting-jet 28 alone suspends a significant portion of the abrasive particles in the waste-fluid 12. As such, by dividing the tank 42 into smaller compartments 56, the cutting-jet 28 maintains at least a substantial portion of the abrasive particles in suspension in the wastefluid 12 within a particular compartment aligned with the cutting-jet 28 without additional mechanical agitation. In general, each compartment is approximately between 1′×1′ and 4′×8′, and more preferably about 2′×4′. As explained in more detail below, the fluid transport mechanism 44 continuously removes waste-fluid 12 and abrasive particles from the compartments 56.

FIG. 2 is a partial cross-sectional view of a portion of the removal system 40 in which the fluid transport system includes a number of conduit sections 60 (identified by reference numbers 60 a and 60 b). The conduit sections 60 are configured in a serial arrangement to transport waste fluid and abrasive particles to the settling container 46 from the compartments 56 a, 56 b and 56 c. The conduit sections 60 include at least a first conduit section 60 a having a first end 62 positioned in the lower portion of compartment 56 b and a second end 64 positioned in compartment 56 a. The first conduit section 60 a also has a first intake opening 66 proximate to the bottom panel 50, a second intake opening 68 located to receive a fluid flow from a conduit section from the adjacent upstream compartment 56 c, and a vent 67 toward the second end 64. The second intake opening 68, for example, can be a funnel. The conduit sections 60 can also include a second conduit section 60 b similar to the first conduit section 60 a, and thus like reference numbers refer to like components. The second conduit section 60 a has a first end 62 positioned in the lower portion of compartment 56 a and a second end 64 coupled to the settling container 46. The second intake opening 68 of the second conduit section 60 b is located to receive a first fluid flow F₁ from the second end 64 of the first conduit section 60 a. Accordingly, the first and second conduit sections 60 a and 60 b define a conduit that transports waste fluid and abrasive particles from the compartments 56 a and 56 b to the settling container 46.

To generate fluid flows through the conduit sections 60, a fluid drive system 70 is preferably coupled to the conduit sections 60 to drive the waste-fluid 12 and the abrasive particles 14 through the conduit sections 60. In this particular embodiment, the fluid drive system 70 includes a fluid driver 71, a primary line 72 coupled to the fluid driver 71, and a plurality of branch feed lines 74 coupled to the primary line 72. The fluid driver 71 can be a pressurized gas source, such as an air compressor. The primary line 72 generally passes through the dividers 52 and 54 to supply pressurized gas to all of the compartments 56. The branch feed lines 74 are attached to the conduit sections 60 below the fluid level of the waste-fluid 12 in the compartments 56. In operation, the pressurized gas source 71 injects a gas 78, such as air, into the conduit sections 60. The gas 78 accordingly rises through the vertical portions of the conduit sections 60 drawing waste-fluid 12 and any abrasive particles 14 suspended in the wastefluid 12 through the conduit sections 60. The gas 78 passes through the vents 67, while the fluid continues to flow through the conduit sections 60. The fluid drive mechanism 70, therefore, generates the first fluid flow F₁ through the first conduit section 60 a and a second fluid flow F₂ through the second conduit section 60 b.

The settling container 46 receives the second fluid flow F₂ from the second conduit section 60 b. The settling container 46 can have a disposable drum 90 and a shroud 92 attached to a rim of the drum 90. The shroud 92 has an inlet 94 coupled to the second end 64 of the second conduit section 60 b, and the shroud 92 has an outlet 96 through which a clarified fluid 16 flows from the settling container 46. As the second fluid flow F₂ enters the shroud inlet 94, the abrasive particles 14 fall downward and form an abrasive particle accumulation 18 in the drum 90. The clarified fluid 16 accordingly rises to the shroud outlet 96. The clarified fluid 16 can then be pumped beck to the compartments 56 in the catch tank 42 (shown schematically in FIG. 1), or it can overflow the container 46 in flow into a drain.

Referring to FIGS. 1 and 2 together, the abrasive removal system 40 removes abrasive particles from at least one of the compartments 56 as the cutting-jet 28 moves along the cutting path P. As the cutting-jet 28 passes over the compartment 56 b, the cutting-jet 28 agitates the waste-fluid 12 to suspend a significant portion of the abrasive particles 14 within the compartment 56 b without additional mechanical agitation. The compartment 56 b allows the cutting-jet 28 to adequately suspend the abrasive particles 14 in the waste-fluid 12 without additional mechanical agitation because the dividers 52 and 54 concentrate the turbulence generated by the cutting-jet 28 and contain the abrasive particles 14 within the relatively small volume of compartment 56 b. The fluid flow F₁ through the first conduit section 60 a accordingly draws a portion of the waste-fluid 12 and the suspended abrasive particles 14 through the first conduit section 60 a. The first fluid flow F₁ exits from the first conduit section 60 a, and the second fluid flow F₂ in the second conduit section 60 a draws the first fluid flow F₁ into the second intake opening 68 of the second conduit section 60 b. The suspended abrasive particles 14 from compartment 56 b are thus transported to the settling container 46 through the first and second conduit sections 60 a and 60 b. The clarified fluid 16 in the settling container 46 can then be returned to the catch tank 42 to maintain a desired fluid level within the tank 42, or the clarified fluid 16 can be disposed of in an environmentally safe manner.

One aspect of the cutting machine 10 is that it reduces the down-time to remove abrasive particles from the catch tank 42 compared to many conventional removal systems. The abrasive particle removal system 40 continuously removes abrasive particles from the catch tank 42 without using additional mechanical agitators to suspend the abrasive particles 14 in the waste fluid 12. By continuously removing the abrasive particles from the catch tank 42, the cutting machine 10 does not need to be shut down for cleaning the catch tank 42. Thus, compared to conventional removal techniques that shut down the cutting machines to allow the abrasive particles to settle, the abrasive particle removal system 40 reduces the down-time of the cutting machine 10.

Additionally, another aspect of the cutting machine 10 is that it is generally less expensive to manufacture and operate than conventional cutting machines with centrifugal abrasive removal systems. As set forth above, conventional centrifugal abrasive systems use large, expensive pumps to suspend the abrasive particles in large catch tanks. The abrasive particle removal system 40, however, divides the catch tank 42 into a plurality of smaller compartments 56 that control the fluid flow within the catch tank 42 so that the cutting-jet 28 suspends the abrasive particles in an active compartment 56 without additional mechanical agitation. The abrasive particle removal system 40 can accordingly use inexpensive, low volume fluid drive systems instead of the large, expensive pumps. Thus, the abrasive particle removal system 40 is less expensive to manufacture and operate than large capacity centrifugal abrasive removal systems.

Still another aspect of the abrasive particle removal system 40 is that it is reliable and does not require a significant amount of maintenance. The removal system 40 has very few moving components, and none of the moving components directly contact the abrasive particles. In contrast to the removal system 40, the conventional conveyor rake and centrifugal removal systems have several moving parts that directly contact the abrasive particles. As such, the abrasive particles can wear down many important components of conventional removal systems (e.g., conveyor rakes, pumps and centrifugal separators). Thus, because the removal system 40 has very few moving parts, it is a reliable system that does not require a significant amount of down-time for maintenance.

FIG. 3 is a partial cross-sectional view of another embodiment of an abrasive particle removal system 140. The abrasive particle removal system 140 illustrated in FIG. 3 is similar to the removal system 40 illustrated in FIG. 2, and thus like reference numbers refer to like components. Referring to FIG. 3, a first conduit section 160 a has a first end 162 positioned in a lower portion of compartment 56 b and a second end 164 positioned in compartment 56 a. Additionally, a second conduit section 160 b has a first end 162 positioned in compartment 56 a and a second end 164 coupled to the shroud inlet 94. Each conduit section 160 a and 160 b has a back-flush valve 69 to control the fluid flows through the conduit sections. Unlike the removal system 40 of FIG. 2, the first ends 162 of the conduit sections 160 have a single intake opening 166. In operation, therefore, the gas 78 from the pressurized gas source 71 rises through the conduit sections 160 a and 160 b to generate the first and second flows F₁ and F₂.

FIG. 3 also illustrates the operation of the back-flush valves 69 in the conduit sections. For example, the abrasive particles in the first flow F₁ may accumulate in an abrasive particle accumulation 118 in compartment 56 a at the first end 162 of the second conduit section 160 b. The abrasive particle accumulation 118 in compartment 56 a may eventually block the intake opening 166 of the second conduit section 160 b. To clear the intake opening 166 in compartment 56 a, the back-flush valve 69 in the second conduit section 56 b is closed. The pressure in the second conduit section 160 b upstream from the backflush valve 69 builds until it blows backward through the intake opening 166. The pressurized gas source 71 accordingly should operate at 70-150 psi to provide sufficient pressure to blow abrasive particle accumulations away from the first end 162 of the second conduit section 160 b.

FIGS. 4 is a partial cross-sectional view of still another embodiment of an abrasive particle removal system. The abrasive particle removal system 240 has conduit sections 260 (identified by reference numbers 260 a and 260 b) with first ends 62 coupled directly to the primary line 72 of the fluid drive system 70. As such, the gas 78 rises through the vertical portions of the conduit sections 260 to draw the fluid through the first and second intake openings 66 and 68. Additionally, a second back-flush valve 79 may be positioned in the primary line 72 after the connection of each conduit section 260. To clear a first conduit section 260 a, for example, the back-flush valve 69 in the first conduit section 260 a and the back-flush valve 79 in compartment 56 b are closed to allow pressure to build within the first conduit section 260 a.

FIG. 5 is a partial cross-sectional view illustrating another abrasive removal system 340 having a conduit 360 with a main conduit section 361 and a plurality of compartment conduit sections 363 (indicated by reference numbers 363 a and 363 b). For example, a first conduit section 363 a has a first end 362 in the lower portion of compartment 56 b and a second end 364 attached to the main conduit section 361. Similarly, a second conduit section 363 b has a first end 362 in the lower portion of compartment 56 a and a second end 364 coupled to the main conduit section 361. In operation, therefore, the fluid drive system 70 draws fluid through the compartment conduit sections 363 and into the main conduit section 361 such that a final fluid flow F_(f) flows through the shroud inlet 94.

FIG. 6 is a partial cross-sectional view illustrating still another abrasive removal system 440 in which the conduit sections 440 (identified by reference numbers 440 a and 440 b) operate in parallel to individually deliver separate fluid flows F₁ and F₂ into the settling container 46. In this embodiment, a first fluid section 440 a has a first end 442a positioned in a lower portion of compartment 56 b and a second end 444 a coupled to the shroud inlet 94. A second conduit section 440 b has a first end 442 b positioned in compartment 56 a and a second end 444 b also coupled to the shroud inlet 94. Thus, in this embodiment, a number of parallel fluid flows are delivered to the settling container 46.

FIG. 7 is a schematic isometric view of another abrasive particle removal system 540 for use with the cutting machine 10. The removal system 540 has a catch tank 542 with a longitudinal divider 552 extending longitudinally along the tank 542 and a number of crossing dividers 554 extending transverse to the longitudinal divider 552. The sidewalls 551 project upward from a bottom panel 550 to an elevation above the top edges of the dividers 552 and 554 such that the level of the waste-fluid 12 can be above the top edges of the dividers. The dividers 552 and 554 may thus be baffles that define a plurality of compartments 556 (identified individually by reference numbers 556 a-556 f) that restrict the fluid flow from one compartment to another, but still allow the fluid to flow over the baffles.

From the foregoing it will be appreciated that, although specific embodiments of the invention have been described herein for purposes of illustration, various modifications may be made without deviating from the spirit and scope of the invention. For example, the fluid driver 71 of the fluid drive system 70 can be a pump or an impeller instead of a pressurized gas source to drive a fluid through the primary line 72 and feed lines 74. Additionally, the removal systems could also be used to remove other solids from a catch tank generated by abrasive or non-abrasive cleaning and/or cutting operations. Such additional applications may be separating paint chips, dirt and other solids from a catch tank in ship cleaning, building cleaning and many other cleaning applications. Accordingly, the invention is not limited except as by the appended claims. 

I claim:
 1. A method of operating a fluid-jet cutting machine, comprising: projecting an abrasive fluid-jet having a plurality of abrasive particles in a fluid through a work-piece and into a tank having a plurality of compartments, and moving the fluid-jet along a cutting path that crosses at least two of the plurality of compartments, each compartment being configured to receive the fluid-jet as the fluid-jet passes across the compartment and each compartment further being configured to concentrate turbulence generated by the fluid-jet in the compartment to maintain a significant portion of abrasive particles in suspension in the fluid in the compartment without additional agitation other than the fluid-jet; transporting a portion of the fluid with suspended abrasive particles from at least one of the plurality of compartments to a settling container; and settling abrasive particles from the transported portion of fluid to leave an accumulation of abrasive particles in a lower portion of the settling container and a clarified liquid above the accumulation of abrasive particles in the settling container.
 2. The method of claim 1 wherein transporting the fluid comprises injecting a pressurized gas into a conduit section in at least one of the plurality of compartments below a fluid level in the compartment, the injected gas rising through a portion of the conduit section to generate a fluid flow through the conduit section that draws abrasive particles out of the compartment.
 3. The method of claim 1 wherein transporting the fluid comprises pumping a fluid through a conduit section to draw suspended abrasive particles out of at least one of the plurality of compartments.
 4. The method of claim 1 wherein: the fluid-jet cutting machine includes a fluid transport system with a first conduit section having a first end in a first compartment and a second end in a second compartment, and a second conduit section having a first end in the second compartment and a second end coupled to the settling container; and transporting the fluid comprises injecting a fluid into the first conduit section to generate a first flow and injecting a fluid into the second conduit section to generate a second flow, the first flow drawing abrasive particles from the first compartment and the second flow drawing abrasive particles from at least the second compartment.
 5. The method of claim 4 wherein injecting a fluid into the conduit sections comprises: pressurizing a gas; and introducing the gas into the conduit sections below a fluid level.
 6. The method of claim 4 wherein injecting a fluid into the conduit sections comprises pumping a liquid through the conduit sections.
 7. The method of claim 1, further comprising clearing an inlet of a conduit between the compartment and the settling container of an accumulation of abrasive particles.
 8. The method of claim 7 wherein clearing the conduit inlet comprises: closing a back-flush valve in the conduit; and injecting air into the conduit between the back-flush valve and the abrasive particle accumulation, the injected air blowing the abrasive particle accumulation from the inlet of the conduit.
 9. A method of operating a fluid-jet cutting machine, comprising: projecting an abrasive fluid-jet having a plurality of abrasive particles in a fluid through a work-piece and into a compartment of a tank; maintaining a significant portion of abrasive particles in suspension in the fluid in the compartment without mechanical agitation other than the fluid-jet; transporting a portion of the fluid with suspended abrasive particles from the compartment to a settling container by injecting a pressurized gas into a conduit section in the compartment below a fluid level in the compartment, the injected gas rising through a portion of the conduit section to generate a fluid flow through the conduit section that draws abrasive particles out of the compartment; and settling abrasive particles from the transported portion of fluid to leave an accumulation of abrasive particles in a lower portion of the settling container and a clarified liquid above the accumulation of abrasive particles in the settling container.
 10. A method of operating a fluid-jet cutting machine, comprising: projecting an abrasive fluid-jet having a plurality of abrasive particles in a fluid through a work-piece and into a compartment of a tank, the tank having at least a first compartment and a second compartment, and a fluid transport system with a first conduit section having a first end in the first compartment and a second end in the second compartment, and a second conduit section having a first end in the second compartment and a second end coupled to a settling container; maintaining a significant portion of abrasive particles in suspension in the fluid in the compartment without mechanical agitation other than the fluid-jet; transporting a portion of the fluid with suspended abrasive particles from the compartment to the settling container comprising pressurizing a gas and introducing the gas into the first conduit section below a fluid level to generate a first flow and pressurizing a gas and introducing the gas into the second conduit section below a fluid level to generate a second flow, the first flow drawing abrasive particles from the first compartment and the second flow drawing abrasive particles from at least the second compartment; and settling abrasive particles from the transported portion of fluid to leave an accumulation of abrasive particles in a lower portion of the settling container and a clarified liquid above the accumulation of abrasive particles in the settling container.
 11. A method of operating a fluid-jet cutting machine, comprising: projecting an abrasive fluid-jet having a plurality of abrasive particles in a fluid through a work-piece and into a compartment of a tank; maintaining a significant portion of abrasive particles in suspension in the fluid in the compartment without mechanical agitation other than the fluid-jet; clearing an inlet of a conduit between the compartment and a settling container of abrasive particle accumulation, comprising closing a back-flush valve in the conduit and injecting air into the conduit between the back-flush valve and the abrasive particle accumulation, the injected air blowing the abrasive particle accumulation from the inlet of the conduit; transporting a portion of the fluid with suspended abrasive particles from the compartment to a settling container; and settling abrasive particles from the transported portion of fluid to leave an accumulation of abrasive particles in a lower portion of the settling container and a clarified liquid above the accumulation of abrasive particles in the settling container. 